Operations on a semiconductor integrated circuit having two kinds of buffers

ABSTRACT

The organization of a frame portion of an integrated circuit chip to include buffers and drivers as well as a power supply for testing functional elements arranged in a &#34;framed&#34; portion of the chip permits smaller drivers and buffers and a lower power supply to be used during later normal operation. The frame portion may be separated completely after testing.

This is a division of application Ser. No. 381,187, filed May 24, 1982, now U.S. Pat. No. 4,488,267.

FIELD OF THE INVENTION

This invention relates to integrated circuit devices and, more particularly, to such devices in which a number of logic, memory and control functions are defined for cooperation, for example, as a microprocessor.

BACKGROUND OF THE INVENTION

Integrated circuit devices typically include a single semiconductor chip in which a number of functional elements are defined as is well understood. These functional elements could include a programmable logic array (PLA), an instruction register, memory, bus lines, etc. as would be present in a microprocessor. These functional elements are laid out on the chip in a manner to conserve space and are connected electrically to peripherally placed lands or pads. Electrical connection to the outside world is made to these pads typically through a hermetically-sealed, dual-in-line package (DIP pack) characterized by two parallel rows of pins.

Electrical interface circuits such as input buffers are commonly associated with some of the peripherally placed pads. Often difficult electrical interface circuits such as output drivers are associated with other pads. Also, both an input buffer and an output driver may be associated with a single pad. Input buffers provide an impedance match to that of the driver as well as any voltage or current translation which may be required. Output drivers provide the voltage and current levels necessary to interface to other chips or devices (i.e., LEDs, transistors, etc.). Both buffers and drivers provide protection from voltage spikes due, for example, to static charge build-up--an especially important consideration for MOS logic, from which many integrated circuits are fabricated.

Many situations exist in which the driver and buffer associated with each pad are unnecessary in the final package; for example, they are necessary only for chip testing to interface with existing test systems. The drivers and buffers, of course, require significant amounts of space and consume significant power. Consequently, the inclusion of the buffers and drivers necessitates larger packages to house the elements and to dissipate heat. Particularly in cases where the final packaged device is to be connected to another integrated circuit with similar input/output characteristics with a minimum of capacitance, the buffers and drivers could be eliminated or reduced in size significantly.

But as stated hereinbefore, the buffers and drivers are necessary for testing. Ideally, the buffers and drivers could be included in the test machine probe card. But, this approach appears unlikely because the capacitance of the test probes alone exceeds the drive capability of the unbuffered MOS drivers. The problem thus is to provide a semiconductor chip with adequate drive capability for testing, yet eliminate unnecessary circuitry in the final product.

BRIEF DESCRIPTION OF THE INVENTION

The invention is based on the realization that a semiconductor chip in which multiple function blocks are defined can be defined in at least first and second separate areas. The first area contains the circuitry (input/output) and pads necessary to interface with test equipment; the second area contains the remaining function blocks. Both areas are equipped with peripheral pads to which external electrical interconnections may be made. In addition, electrical connections are formed between the pads of the second area and the input/output circuitry of the first area, in a manner to permit testing.

In one embodiment, a first area is defined with pads and I/O circuitry in a partial frame geometry to encompass a second area. The second area contains all the remaining function blocks and a number of pads corresponding to the number in the frame. But the second area includes minimal I/O circuitry. Fine line, electrically conducting patterns connect the pads of the two areas. After testing, the conducting patterns are severed leaving a fully functioning device without the unnecessary I/O circuitry. Either a subset or all of the pads of an integrated circuit could be configured this way.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an enlarged schematic block diagram of the functional layout of a prior art integrated circuit (IC) chip;

FIG. 2 shows a schematic block diagram of a variety of cooperating IC chips on a PC board;

FIG. 3 shows an enlarged schematic block diagram of the functional layout of an IC chip in accordance with this invention; and

FIGS. 4 and 5 are schematic circuit diagrams of portions of the chip of FIG. 3.

DETAILED DESCRIPTION

FIG. 1 shows a semiconductor, integrated circuit chip 10. The chip has defined within it a plurality of functional areas which are represented as (function) blocks 11, 12, 13, 14 and 15. Block 11 represents a microcode memory, block 12 represents a decoder; 13 represents another microcode memory. Block 14 represents a microprogram counter path and block 15 represents the data path. This organization of an illustrative prior art chip is shown and discussed in An Introduction to VLSI Systems, Carver Mead and Lynn Conway, 1980, Addison-Wesley, at page 203.

Chip 10 also includes a number of pads 20-22, 24-27, 29-32, 33-36, 40, and 41. Pads 20-22, 29 and 35 are encompassed by U-shaped blocks 20', 21', 22', 29' and 35' which represent both driver and buffer input/output (I/O) circuitry. Interconnections to off-chip elements for both input and output operations are made through the associated pads, and any one of which can be simply termed a "buffer" for the purpose of convenience.

Other pads are adapted either for input or output operations but not both. For example, pads 24, 25, 32, 33, 34 and 36 have L-shaped blocks 24', 25', 32', 33', 34' and 36' associated with them. These pads are adapted by such circuitry for output operations only. Similarly, pads 26, 27, 30, and 31 have circuitry represented by L-shaped blocks 26', 27', 30' and 31' associated with them. Pads 26, 27, 30 and 31 are adapted by the circuitry for input operations only. The various pads and associated circuitry dictate the permissible interconnections between the chip of FIG. 1 and others with which that chip will cooperate in a system environment.

The system enbironment is defined by interconnections between chips often secured to a printed circuit (PC) board. FIG. 2 shows one such board 50 to which chip 10 is secured in the usual manner. FIG. 2 shows several other chips 52, 53, 54 and 56 secured to board 50 also.

Interconnections between the chips required different power levels depending on the nature of the cooperation between the chips. Interconnections where several connections occur require high drive capability. Double-headed arrow 60 represents one set of such I/O interconnections to off-chip elements and electrical conductor 61, which would be connected, say, to pad 22 of FIG. 1, requires, say, a 5 volt power supply. Electrical conductors 64 and 65 may be involved only with output operations requiring low current and voltage. These conductors may be connected to pads 31 and 36 of FIG. 1, respectively. Conductor 66 connected between chips 10 and 52 may be involved only with inputs to chip 10 requiring low voltage. Land 34 of FIG. 1 is suitable for connection to conductor 65. Other chips 54 and 56 are similarly interconnected. But the interconnections are not shown or described. Suffice it to say that a PC board houses many chips with interconnections between them and to elements external to the board and that the power (or the electrical interface in general) required at a particular pad differs depending upon the function served and the number of interconnections to that pad. Pads 40 and 41 are the power pad and ground, respectively, for a power supply of, say, 5 volts.

But testing frequently requires high power at every pad. Consequently, relatively large and high capacitance circuitry is required around each pad in prior art circuits for providing such power even though normal operation permits low power operation and concomitant low capacitance.

FIG. 3 shows an arrangement in accordance with this invention where the circuit of the type enclosed within broken line 70 of FIG. 1 is shown in environment which permits testing at high power and normal operation at various power levels without any speed penalty associated with unnecessary high capacitance circuitry. Notice that two sets of pads are shown. One set is numbered, along with associated driver circuitry, to correspond to pads and circuitry in FIG. 1 except preceded by the digit 1. Connection to the external world for testing is made via these pads. An additional pad, 141, is included for connection to a 5 volt power supply and is electrically connected in series to the I/O circuitry associated with all the pads 120-122, 124-127 and 129-132. Also, a ground connection may be made to each pad from pad 143.

The circuitry associated with each pad 120-122, 124-127 and 129-132 is electrically connected to a second internal pad shown within the area defined by imaginary demarcation line 150 which separates the chip into a first (partial frame area) and a second (framed) area. These pads are identified to correspond with the associated pads but are preceded by a numeral 2 rather than 1. The associated circuitry is identified similarly but with a prime (') added. Also within the area defined by line 150 is included a, say, 2.5 volt power pad 260 and a ground pad 261 for powering all circuits 220'-222', 224'-227' and 229'-232'.

Testing is carried out through the outer pads. Thereafter, the chip is (laser or diamond) scribed along broken line 270 breaking all the electrical connections between circuitry 120' to 132' and pads 220 to 232.

FIG. 4 represents a typical (output) arrangement of an associated pair of pads and circuitry in FIG. 3. For example, the output circuit arrangement comprising circuits 232' and 132' along with pads 232 and 132 are represented. Typically driver circuit 132' is much larger than driver circuit 232' and has a much larger current drain associated with it. When the interconnection between circuit 132' and pad 232 is severed along line 270, the larger current drain is no longer of significance.

The portion of the chip outside of line 270 may be separated completely if desired. But it may be left in place if it is desired to use the 5 volt power supply as well as the 2.5 volt supply. For example, pin out connections could be made to both sets of pads for interfacing to two different voltage levels.

FIG. 5 represents a typical (input) arrangement of, say, elements 131, 131', 231 and 231' of FIG. 3. In this instance, driver 131' is much larger than driver 231'. Still, when the interconnection between circuit 131' and pad 231 is severed at 270, drive requirements are relatively low for later normal operation. The 5 volt supply need be provided only for testing and may then be thrown away if not used to advantage. By eliminating the electrical load associated with relatively larger drivers (and buffers) and particularly by employing relatively small circuits 220' to 232' of FIG. 3, current drain during normal operation is significantly reduced. This reduction leads to a significant increase, typically doubling, in operating speeds of the chip from, say, 6 to 12 megahertz.

The frame portion of the chip may be used to permit increased design flexibility to optimize local communication between different elements on a circuit board to, for example, use smaller drivers to reduce the number of cycles necessary for a given operation. For example, lower input impedance results in faster signal rise time.

The principles of the invention may be turned to account to design a chip requiring at least two distinct sets of interface requirements (i.e., voltage, power, impedance, size, etc.) of which normal microprocessor operation and testing constitute just one example. 

What is claimed is:
 1. The method of forming a semiconductor integrated circuit chip portion comprising the steps of:(a) providing a larger integrated circuit chip of which the chip circuit portion is a part, the chip portion comprising a first plurality of first bonding pads each of which is separately connected to a separate buffer of a first kind that operates with a first supply voltage, the larger chip exclusive of the chip portion comprising a second plurality of second bonding pads each of which is separately connected to a separate buffer of a second kind that operates with a second supply voltage different from the first voltage, each buffer of the second kind being separately connected via a separate electrically conductive path to a separate corresponding one of the first bonding pads, the chip portion being capable of performing first electrical operations in response to first signals applied to the first bonding pads and being capable of performing second operations in response to second signals applied to the second bonding pads; (b) performing at least one of the second operations by applying the second signals to the second bonding pads; and (c) disconnecting at least one of the buffers of the second kind from its corresponding one of the first pads by physically severing the corresponding electrically conductive path.
 2. The method of claim 1 in which all of the buffers of the second kind are electrically disconnected from all of the corresponding first pads, in step (c).
 3. The method of claim 2 in which the chip portion is severed completely from the larger chip exclusive of the chip portion, in step (c).
 4. The method of claim 3 in which the first operation is a normal operation and the second operation is a test operation.
 5. The method of claim 2 in which the first operation is a normal operation and the second operation is a test operation.
 6. The method of claim 1 in which the first operation is a normal micropessor operation and the second operation is a test operation.
 7. The method of operating a semiconductor integrated circuit chip portion comprising the steps recited in claim 1 followed by the step of performing at least one of the first operations by applying the first signals to the first bonding pads. 